EP0435029A2 - Data carrier with a liquid crystal security element - Google Patents

Abstract

Data carriers protected against forgery attempts using colour copiers, such as an identity card or a security, which include an optically variable security element of a liquid crystal material. This security element, such as for example a security thread, has a layer similar to plastic of a liquid crystal polymer, which exhibits a pronounced iridescence at room temperature. The plastic-like properties of the liquid crystal polymers permit easy processing to form a semi-finished or finished product, so that very diverse types of security elements can be produced. <IMAGE>

Description

The invention relates to data carriers, in particular securities, documents, identity cards or the like. With an optically variable security element that contains a liquid crystal material. Because of the easier readability, the abbreviation FK for liquid crystal is often used in the following.

The increasing technical maturity of color copiers leads to copies that are less and less distinguishable from the originals in terms of color, resolution and quality. To protect against counterfeiting with the help of color copiers or scanners, the use of optically variable elements as security elements is increasingly being propagated for data carriers. Such elements have in common that they have different color or brightness renditions depending on the lighting and viewing conditions. The most common optically variable elements include diffraction gratings, holograms, interference coatings, metameric colors and polarizing coatings.

Holograms and gratings are based on diffraction effects. Interference coatings usually consist of several superimposed layers, the layer thicknesses being the size of the wavelength of the light.

Metameric printing inks usually consist of mixtures of pigments with different reflectance bands. This composition causes the metameric colors to change their visual color impression when the type of lighting is changed.

Dichroic dyes have the property of absorbing white light in different wavelength ranges depending on the direction of polarization. The result is a polarization-dependent color impression.

A disadvantage of the known optically variable authenticity features is that they are either very expensive to manufacture, cannot be processed with conventional manufacturing processes, or are only compatible to a limited extent with other authenticity features or card elements.

The object of the invention is to propose a feature which is effective as a copy protection and which has viewing angle-dependent effects, which can be produced inexpensively and by conventional methods and is compatible or combinable with other features.

The object is achieved by the features mentioned in the characterizing part of the main claim. Developments are mentioned in the secondary and subordinate claims.

The invention is based on the use of liquid crystal polymers as security elements. After suitable oriented production at room temperature, these polymers represent a plastic-like solid with a pronounced interplay of colors. Such a suitable production process consists, for example, of doctoring the still liquid material onto a base and then curing it by UV radiation. Liquid crystal polymers and cholesteric organopolysiloxanes are particularly suitable as liquid crystal polymers. Suitable liquid crystal polymers, their chemical structure and their preparation are described in the published patent applications EP-OS 0 136 501, EP-OS 0 060 335 and EP-PS 0 066 137. Reference is expressly made to the disclosure content of these publications.

The use of conventional liquid crystals as a security element is already known and is proposed, for example, in AU-PS 488 652 (Commonwealth). This document describes a laminated Banknote with an intermediate layer in which a security element in the form of a liquid crystal material is embedded. The FK material is printed on an ticking. The liquid crystals are in a liquid state and, embedded in microcapsules that are closed on all sides, are mixed with a printing ink. The authenticity is checked by changing the color of the security element as a result of a change in temperature.

In spite of structural anisotropy, liquid crystals usually behave like a liquid, which is why it is necessary to enclose these materials in capsules or cavities. This results in a complicated manufacturing technique. In addition to the complex encapsulation of the LC materials, it is not possible due to the risk of injury to the cavities or capsules to embed the proposed security elements in the conventional manner under pressure and heat (classic laminating technology) in foils or identity papers. Encapsulated liquid crystals are also unsuitable as security elements on banknotes or securities with steel intaglio printing, since the high pressure loads required in this manufacturing process lead to the destruction of the capsules and cavities.

However, liquid crystals can also be in solid form after appropriate processing and, depending on the processing method, have a high-grade alignment of their molecules, as a result of which the optically variable properties emerge in full and in full brilliance. In the LC systems according to the invention, the color purity of the reflected light rarely exceeds a range of 100 nm, the color change effects with the change in the viewing angle are very pronounced, and the reflected and transmitted light has a pronounced circular polarization. The fully trained Optically variable properties make such LC polymers particularly suitable for use as a security element on data carriers, securities and ID cards. The color changing games are easy to observe even for laypeople. The wavelength-selective reflectivity and the polarization effects make the material highly suitable for automated testing. The variety and distinctiveness of the optical effects make it difficult to create fake impressions. In practically all embodiments, the FK elements can also be used both as machine-readable authenticity features and together with other machine features. Due to the IR permeability of the LC polymers, the other machine features can also be arranged under the LC polymers under certain circumstances.

The solid state properties of the FK polymers make it considerably easier to manufacture security elements from them. Firstly, there is no need to enclose the liquid crystals in a hollow body, and secondly there is no risk of the liquid crystals bursting open and escaping during subsequent processing steps and during the lifetime of the data carrier. The manufacturing processes and the application are extremely easy.

The plastic-like properties of the liquid crystal polymers enable easy processing into semi-finished or finished products. The starting material is generally in the form of granules and can be shaped and further processed using the methods and machines known from plastics production. This makes it possible in the field of security technology to manufacture completely different types of security elements on the basis of LC polymers and to cover different applications.

Carrier webs made of a tear-resistant plastic can be coated with a layer of LC polymers. The resulting web of material can then be cut into narrow webs or threads that can be embedded as security threads in paper or other materials.

As an alternative to this, multilayer film webs can also be produced which contain an embedded layer made of an LC polymer. Such webs can be designed as adhesive tapes or transfer tapes, which are suitable for gluing or stamping transfer elements on paper or plastic surfaces.

Finally, LC polymers can also be produced as self-supporting films. These foils can be used, for example, as foil layers for multi-layer ID cards.

Further advantages and features of the invention result from the subordinate and subordinate claims as well as the following figures and exemplary embodiments.

Show it:

Fig. 1

 the spectral transmission and reflection properties of LC polymers under different viewing angles,

Fig. 2

 a banknote with a window security thread with one or more layers of LC polymers,

Fig. 3

 a security thread with a layer of an FK polymer,

Fig. 4

a symmetrical security thread with external layers of FK polymers,

Fig. 5

 a symmetrical security thread with internal layers made of FK polymers,

6a, b

 a printed, symmetrical window security thread in cross-section and top view,

7a, b

 a printed security thread with movement effects in cross-section and supervision,

8a, b

 an identification card with a transfer element with an LC layer in supervision and as a sectional view,

9a, b

 an identification card with a visually unreadable coding that is covered by the security element,

Fig. 10

 a cross section through a transfer belt,

Fig. 11

 the transfer of an LC security element to a substrate,

Fig. 12

 an ID card with a laminated layer of FK polymer,

Fig. 13

 a test arrangement for FK security elements,

14, 15

 Detector arrangements for the detection of LC security elements.

The applications and effects of the liquid crystal polymers explained in the figures and exemplary embodiments To make it easy to understand, some important properties of these substances are explained in advance.

LC polymers are a special variant of liquid crystals, in which the liquid crystalline state is "frozen" in a polymer matrix, whereby the optical properties are particularly significant. For example, liquid crystal polymers normally do not absorb light, and their color is created by multiple interference of light at the individual crystal planes. The color impression in reflected and transmitted light is accordingly different. The reflected color spectrum contains only a narrow frequency range around a central wavelength and therefore shows a high color saturation. The transmitted spectrum is complementary to the reflected spectrum and has a dip in the region around the central wavelength.

When using the LC polymers on opaque substrates, a particularly high color purity is achieved for all viewing angles if the liquid crystal layer is applied to a black background. The reflected spectrum is then undisturbed by secondary reflections on the background.

The lattice constants of oriented LC polymers according to the invention can be set in the range from 300 nm to 1000 nm or defined in the synthesis, so that the reflected central wavelength is in the near infrared or in the visible in the case of perpendicular incidence. As the observation angle becomes flatter, the central wavelength of the reflection band shifts in the direction of shorter wavelengths. For example, the wavelength reflected in the top view is about 20% larger than the reflection at 60 °.

1 shows the spectral reflection R of an FC layer with vertically incident illumination in curve 1 and with an illumination direction of 60 ° in curve 2. The color impression can accordingly for special LC polymers from green to violet, from yellow to blue, from light red to change green or, in the case of an IR reflection band, from black to red. The lattice constant and thus the basic color of the liquid crystal polymer depends on the exact chemical structure of the liquid crystal and can be set in a defined manner in the range between 300 and 1000 nm by the synthesis conditions.

Fig. 2 shows an application of an FK polymer for a window security thread. A security thread 13 has been embedded in a bank note 11 with a security print image 12 during the paper production in such a way that it comes to rest on the surface of the paper in the windows 14 and is thus visually recognizable. Depending on the embodiment, the width of such security threads fluctuates between 0.5 and a few millimeters.

In order to provide copy protection for the banknote by optically variable effects, the security thread 13 is formed in such a way that it contains one or more layers of an LC polymer. Variants for the production and for the construction of security threads are shown in FIGS. 3-7.

3 shows in cross section a first variant for a security thread 13a; it consists of a plastic carrier 20, preferably a polyester film with a typical thickness of 20-100 micrometers is used for this. The carrier 20 is coated on one side with a layer 21 made of an LC polymer that is several micrometers thick. In order to optically emphasize the color change interactions of the liquid crystals, the film 20 is preferred colored black. The thread is oriented during papermaking so that the liquid crystal layer is on the visible outer surface.

4 shows in cross section as a further variant a security thread 13b with a symmetrical layer structure. Symmetrically constructed security threads have the advantage that one does not have to pay attention to the orientation of the thread during embedding in the paper. The thread 13b consists of two carrier films 20, both of which are coated on one side from a layer 21 of LC polymers. The carrier films 20 are connected to one another by a laminating agent 22 in such a way that a symmetrical layer structure with external LC layers is produced. In order to increase the color richness, the carrier webs 20 and / or the lamination mediator 22 can optionally be colored with transparent or pigment colors. A solution that is simple in terms of production technology is to color only the lamination mediator 22, preferably an opaque black is used for this.

5 shows a further variant of a symmetrically constructed security thread 13c in cross section. In contrast to FIG. 3, the carrier films 20 now lie on the outer sides of the thread 13c and thus protect the internal LC layers 21 from damage. In this variant, preferably only the laminating agent is colored with a dye. Since the outer carrier layers 20 must remain transparent, they are either not colored at all or only weakly.

6a and 6b show a further variant of a security thread 13d in cross section (FIG. 6a) and in supervision (FIG. 6b). 5, the thread 13d has a symmetrical layer structure consisting of two carrier films 20, two LC layers 21 and an adhesive layer 22. As part of a manufacturing process, the thread was assembled from two coated pairs of foils 30, 31. Before the assembly, the surface 33 of one of the two pairs of foils was provided with a printed image 34 made of black color, and alphanumeric characters were applied to the surface of an LC polymer layer in a conventional printing process in micro script. In addition, a transparent laminating agent 22 was used. In transmitted light, the characters appear black in the window areas of the paper against the optically variable color background of the polymer layer. In contrast, only the micro characters show a color change in reflected light.

In another variant of the security thread of FIGS. 6a and 6b, the characters 34 are applied in green microprint on one of the LC layers, while the lamination agent 22 is colored black. At the same time, the LC material is selected so that it appears green under a certain viewing angle, for example under vertical incidence on the black background. When observing the security thread at this angle, the entire area appears green. When the viewing angle changes, the color of the FK polymer layer changes, while in the font the green color remains dominant. The result is a security thread, the writing of which only becomes visible when the thread is tilted.

7a and 7b show a further variant 13e in cross section (FIG. 7a) and in supervision (FIG. 7b). The security thread consists of a carrier film 20 and a layer 21 made of LC polymers. The polymer layer was printed in a conventional printing process with a pattern of differently colored, diagonally extending strips 40. In the example shown, red 41, yellow 42, green 43, blue 44 was selected as a special color sequence for the pattern 40, the pattern changing as often as desired repeated over the thread length. When looking at this security thread 13e, the colored surface areas 40 each appear with different color effects through the LC layer. The color spectrum of the individual areas is made up of the reflection band of the printed dyes. In addition, the colors of the liquid crystal layer are mixed in additively. Due to the angle-dependent reflection characteristics of the LC polymers, with an appropriate color coordination of the LC polymer with the color strips with the arrangement shown, when the thread is tilted, the illusion of a colored strip moving along the thread can be created. Analogously to FIG. 5, this embodiment variant can also be expanded to form a security thread with a symmetrical layer structure.

The variants shown in FIGS. 3-7 can be varied in many ways depending on the desired appearance. The optically variable effects of the FK polymers can be combined by coloring any layers with "classic" colors, whereby both transparent dyes and pigment dyes can be used as dyes. The dyes themselves can be incorporated in any layer (also in the LC layer, but then only in low concentrations) of the security thread and / or can be applied as a printed image on any layer of the thread.

The colors indicated in the description of the figures are only to be understood as suggestions; the colors indicated can be replaced by other dyes as desired. These possible combinations result in an enormous variety of possible color variations, color illusions and kinetic effects.

The variants of security threads shown in FIGS. 3-7 can be produced on the basis of a single semi-finished product. To produce the semi-finished product, a film web 20 made of a carrier material such as polyester plastic is coated with a layer 21 made of LC polymers. Depending on the color design of the security thread, printed, transparent or colored carrier foils are used. The thickness of the film web is preferably in the range of less than a tenth of a millimeter, and a film thickness of approximately 10 micrometers is usually sufficient for the LC coating. Due to the manufacturing process, the typical web widths of the semi-finished product are in the range of one meter.

To produce printed security threads, the carrier web and / or the LC layer are printed with the desired patterns or characters on known printing machines in a suitable manufacturing process. For the production of multi-layer, above all symmetrically constructed security threads, the coated and possibly printed film webs are placed on top of one another and connected with a laminating agent.

Only after the webs have the desired layer structure are they cut into the threads on known cutting devices. The final thread width is between 0.5 and 5.0 mm, depending on the intended use. The threads thus obtained are particularly suitable for embedding in paper, but can also be embedded between the plastic layers of an identification card.

Another class of security elements are the transfer elements, they are often applied to credit cards, ID cards, banknotes, securities and the like in order to protect them against counterfeiting and in particular against copying. Security elements on the basis are also suitable for these purposes of FK polymers due to their optically variable properties. The transfer elements are transferred from carrier tapes to the surface of the objects to be protected using the transfer method.

8a and 8b show an identification card 50 with a symbolically indicated data record 49 and with a transfer security element 51 in supervision and as a sectional view. The security element 51 contains a layer made of an FK polymer, which is why it has the color change interactions typical of these materials.

Transfer elements usually consist of several layers, FIG. 8b shows a section through the identification card along the line I / I. In the figure, the height of the element is shown exaggerated, usually it is only a few 10 micrometers. An adhesive layer 54, a protective lacquer layer 55, an LC layer 56 and a protective lacquer layer 57 that closes off on the outside lie one after the other on the substrate 53. This security element, which is shown here in a very simple embodiment, can be varied in many different ways.

The possibilities for the color design of the FK elements are analogous to the security threads. If you attach importance to visually clearly recognizable color changes, then you prefer to color the surface black. To add a color to the reflected spectrum, as shown in FIG. 8a, the element 51 was applied to a printed background 60. The printed image can be varied in many ways, a simple design is a single-colored background, an improved optical effect has a multi-color printed background with contrasting alphanumeric characters or patterns such as diagonally running colored stripes, nested colored circles, etc. Particularly interesting effects if the background 60 contains a black and white or color photograph, a signature, and the like.

Similar color effects as when printing on the background can be achieved by dyeing, printing or labeling suitable optically effective layers of the transfer element, which do not change during transfer.

As will be explained later, the transfer principle enables the optical element to be given any external outline. The coat of arms shape 61 shown in FIG. 8 therefore represents a stripe, a seal, a company logo, an alphanumeric character, a number, guilloche pattern, etc. The shape of the outline 61 gives the optically variable element an individual expression.

9a and 9b show a top view and a sectional view of an application variant in which map data are concealed with an FK element and are concealed and protected from falsification. FK polymers with visually visible color change interactions are mostly transparent in the infrared and can therefore be effortlessly combined with codes that can be read in the infrared range. In a first printing process, a code 72 was applied to the surface of a card 70 with an IR-absorbing ink 71. In the next step, this IR coding 72 was overprinted with an IR-transparent opaque color 73, but opaque in the visible spectral range. In the last step, an LC security element 74 was then sealed onto the covering color 73 in this area.

For reasons of production technology, the transfer principle is preferred for applying security elements made of LC polymer to the surface of a substrate. With this In principle, a transfer belt is produced in a first process step, then in a second process step the security element is detached from the transfer belt and connected to the substrate.

10 shows the structure of a transfer belt 100 in cross section, as is suitable for applying security elements with an LC layer to a substrate surface. On a carrier film 101 there are successively a wax layer 102, a protective lacquer layer 103, a layer made of an FK polymer 104, a color layer 105 and a hot glue layer 106. The carrier film preferably consists of a tear-resistant plastic polyester with a thickness in the range of less than one tenths of a millimeter. The remaining layers of a transfer belt usually have a thickness of a few micrometers to a few tens of micrometers. The layers 103-106 lying on the wax layer form the later security element. To achieve color effects, the transfer ribbon can be colored or printed in different layers during its manufacture.

To apply the security element to the substrate, the transfer tape 100, as shown in FIG. 11, is placed with the hot-melt adhesive layer 106 on the substrate 111 and pressed. The pressing takes place with a heated transfer stamp 112 or alternatively also with a transfer roller. The hot-melt adhesive layer bonds to the substrate under the influence of pressure and heat. At the same time, the separating layer 102 melts and enables the carrier material 101 to be pulled off. The security element is only connected to the substrate in the surface areas in which the separating layer has become liquid, ie only in the surface areas heated by the transfer stamp. In the other surface areas, the layer structure and the carrier material remain firmly connected. When removing the carrier film from the substrate the layer structure tears along the contour edges 113 of the transfer stamp, whereby the contour 113 of the transferred security element always corresponds to the contour of the embossing stamp. In this way, even complicated outline structures such as company logos, block letters and the like can be realized. The process of heat sealing as such is known and is described for example in DE-OS 33 08 831.

FK polymers can also be processed into films. In this form, they are particularly suitable as large or full-surface security elements for multi-layer ID cards.

12a and 12b show, for example, a laminated identification card 120, which consists of a paper insert 121 and two external thermoplastic cover foils 122 and 123. The layers are pressed into a compact ID card under pressure and heat. The card information is usually printed on the ticker, which in the example shown has an image of the holder 124, card data 125 and a company logo 126. To increase the security against counterfeiting, a film made of FK polymer 127 was inserted into the card structure between the ticking and the top cover film in the left half of the card. The color change interactions of the liquid crystal film can be observed through the transparent cover film, with the colored printed company logo 126 additionally adding color effects.

Some LC compounds cross-link under the influence of high-energy (e.g. UV) radiation and only then form a chemically stable film. Unexposed, ie uncured areas can be removed with solvents. Analogous to the known phototechnical processes in semiconductor and printing plate production technology, a defined area of an LC film can be produced in this way exposed through a mask and then the coating is chemically removed in the unexposed areas, so that patterns, letters, numbers etc. are formed.

Of course, it is also possible to cover the entire card area with the film made of liquid crystal polymer. An alternative to adding a film to the card structure is to transfer the liquid crystal element to the ticking in accordance with the transfer principle before laminating. A further variant consists in replacing one or both cover foils 122, 123 as a whole in the usual construction of laminated cards with an FK foil.

Films made of Fk materials are suitable as large or full-surface security elements. Such films are preferably made from a liquid crystal substance. In order to obtain a film suitable for security purposes, the LC substance is processed on a roller mill. The alignment of the liquid crystal molecules necessary for the optical effects takes place through shear forces that occur during rolling. The film material produced in this way is particularly suitable for the production of identity cards, but can also be processed into other authenticity indicators, such as a security thread.

The polarization properties and their wavelength selectivity are particularly suitable for machine testing of authenticity indicators on the basis of the liquid crystal polymers according to the invention. The reflected light is initially narrowed spectrally over a range around the central wavelength, furthermore unpolarized light is broken down into liquid-crystal components into right and left rotating components. Depending on the chemical composition of the polymer, only one of the two parts is reflected, while the complementary part is transmitted.

One possibility for machine testing is shown below on a film made of FK polymer, which is located on a black, completely absorbent carrier 128. As shown in FIG. 13, the element 130 is illuminated at a predetermined angle with an unpolarized light beam 131, for example an incandescent lamp 129. After the reflection, the light beam 132 strikes the detector system 133 shown in FIG. 14, with which the detection of the spectral filtering and the circular polarization is carried out.

The construction of the detector system 133 is shown in FIG. 14. Within the detector system 133, the reflected beam 132 first passes through a color filter 141 which only allows light of the expected central wavelength to pass. The light beam then strikes a lambda / 4 plate 142, which converts the circular polarization into a linear polarization. The light then falls on a 1: 1 beam splitter 143, from where the two partial beams 144, 145 reach two detectors 146, 147 with polarization filters 148, 149 arranged in front of them. The polarization planes 150, 151 of the two filters are perpendicular to one another, at the same time they are aligned at 45 ° to the two optical axes of the lambda / 4 plate.

• A) Echtes Element
  Das reflektierte Licht passiert ungehindert den Farbfilter. In der Lambda/4-Platte wird aus der zirkularen eine lineare, entweder horizontal oder vertikal stehende Polarisation erzeugt. Die lineare Polarisation führt dazu, daß einer der beiden Detektoren 146, 147 die volle Intensität empfängt, während der zweite Detektor kein Licht erhält.
• B) Gefälschtes, unpolarisiert reflektierendes Element
  Das spektral korrekte, aber unpolarisiert reflektierte Licht weist auch nach dem Passieren der Lambda/4-Platte keine bevorzugte Polarisationsrichtung auf. Beide Detektoren empfangen je 50 % des reflektierten Lichts.
• C) Gefälschtes Element mit Spektralfehler
  Das reflektierte Licht wird im Farbfilter 142 absorbiert, entsprechend empfängt keiner der beiden Detektoren ein Signal.
• D) Gefälschtes linear polarisierendes Element
  Die 45°-Anordnung von Lambda/4-Platte und den beiden Polaristoren führt dazu, daß unabhängig von der ursprünglichen Polarisationsrichtung des reflektierten Lichts beide Detektoren das gleiche Signal empfangen.

The machine authenticity check is based on an analysis of the two detector signals. The mode of operation of the detector system is shown below in several cases.

• A) Real element
  The reflected light passes freely through the color filter. In the Lambda / 4 plate, the circular produces a linear polarization, either horizontal or vertical. The linear polarization means that one of the two detectors 146, 147 receives the full intensity, while the second detector receives no light.
• B) Fake, non-polarized reflective element
  The spectrally correct, but non-polarized reflected light does not have a preferred polarization direction even after passing through the lambda / 4 plate. Both detectors each receive 50% of the reflected light.
• C) Counterfeit element with spectral error
  The reflected light is absorbed in the color filter 142, and accordingly neither of the two detectors receives a signal.
• D) Counterfeit linear polarizing element
  The 45 ° arrangement of the lambda / 4 plate and the two polaristors means that both detectors receive the same signal regardless of the original polarization direction of the reflected light.

In order to increase the error significance, several detector systems can also be used to test a single element; which are arranged at different angles, for example, and react accordingly to different central wavelengths.

It is clear to the person skilled in the art that the detector system can be implemented in many ways. 15 shows an arrangement underneath as a maintenance-friendly alternative Use of optical fibers. The basis of the optical arrangement is again FIG. 13. In the detector system 133, the reflected light beam 132 first passes through a color filter 161 for checking the central wavelength. In the following Lambda / 4 plate 162, the circular polarization is converted into a linear one. A coupling optic 153 couples the light beam 132 into a light guide system 154, known beam switches separate the beam into equivalent partial bundles. At the end of each sub-bundle there is a pair of polarizer-detectors 155/156 and 157/158 for the two different directions of polarization.

With light of the correct wavelength and polarization, one of the two detectors 156/158 receives 50% of the input intensity (in the case of lossless optics), the second receives no light. In the case of a fake element with unpolarized reflected light, each of the two detectors receives 50% of the input intensity. In this way, counterfeit and original can be distinguished.

Claims (33)

Data carrier, in particular security, document, ID card or the like. With an optically variable security element which contains a liquid crystal material, characterized in that the material is a liquid crystal polymer which is present in an oriented form and at room temperature as a solid. A data carrier according to claim 1, characterized in that the material is a cross-linkable liquid crystal silicone polymer. A data carrier according to claim 1, characterized in that the material is an organopolysiloxane or an organooxysilane or represents a compound with an organopolysiloxane or an organooxysilane. A data carrier according to claim 1, characterized in that the liquid crystal polymer is present as a layer or film in the security element or in the data carrier. A data carrier according to claim 4, characterized in that the carrier films (20) coated with liquid crystal polymer are joined together in pairs with a laminating agent (22) in such a way that a symmetrical layer structure (13c, 13d) is produced. Data carrier according to claim 4, characterized in that at least one surface of the security element is printed with transparent absorbing and / or reflecting colors (34, 40) or a layer of the security element is colored with such colors. Data carrier according to claim 6, characterized in that the security element is applied in a printed and / or labeled area (60) of the data carrier. Data carrier according to claim 7, characterized in that a visually invisible coding (72) is applied to the data carrier in the area of the security element. Data carrier according to at least one of Claims 1 to 8, characterized in that the liquid crystal polymer is processed as a film (127). Data carrier according to claim 9, characterized in that the film (127) is inserted as a security element in the structure of a multi-layer data carrier (120). Data carrier according to Claim 10, characterized in that the film is the cover film (122, 123) of the data carrier. Optically variable security element for equipping data carriers with liquid crystal material, characterized in that the security element is designed as a multilayer transfer element with at least one layer (56) made of liquid crystal polymers. Security element according to claim 12, characterized in that layers or surfaces of the transfer element are printed or colored with transparent absorbent and / or reflective dyes. Security element according to claim 12 or 13, characterized in that the outline (61) of the transfer element has a predetermined shape in the form of a logo, a seal, a coat of arms, alphanumeric characters, guilloche patterns or the like. Semi-finished product for the production of a security element according to at least one of claims 12 to 14, characterized in that a layer (21) or a film (21) made of a liquid crystal polymer is applied to a carrier film (20). Semi-finished product for producing a security element according to claim 15, characterized in that two coated carrier foils (20) with one Laminating mediators (22) are joined together in such a way that a symmetrical layer structure is present. Semi-finished product according to claims 15 or 16, characterized in that a layer or surface of the semi-finished product is printed with dyes and / or colored. Semi-finished product according to at least one of claims 12 to 14, characterized in that it consists of at least one carrier tape and a separating layer, a layer with liquid crystal polymer. Method for producing a data carrier according to at least one of the preceding claims, characterized by the following steps: Applying the still liquid liquid crystal material to a support surface, Orientation of the liquid crystal material by mechanical action of shear forces, - hardening of the oriented material to solid, - Introducing or applying the liquid crystal solid material in or on the layer structure of the data carrier. A method according to claim 19, characterized in that the carrier surface is a separate carrier film. A method according to claim 19 or 20, characterized in that the orientation is carried out by doctoring the liquid crystal material. A method according to claim 19, characterized in that the carrier surface is a printing roller onto which the liquid crystal material is directly doctored or rolled and from which the liquid crystal material is transferred to a surface of the data carrier by a printing process. A method according to claim 19, characterized in that the curing is carried out by a defined supply of energy. A method according to claim 23, characterized in that the energy is supplied by irradiation with UV or IR light. A method according to claim 23, characterized in that the energy is supplied by the action of an electron beam. A method according to claim 19, characterized in that the liquid crystal material forms a self-supporting film on the support surface, which is removed after curing. A method for producing a data carrier according to at least one of claims 1-18, characterized in that the liquid crystal material is arranged in an oriented and hardened form on a carrier film and is transferred from this carrier film to the data carrier or a layer of the data carrier in the transfer process. Method according to at least one of claims 19 to 27, characterized in that the hardening of the liquid crystal material does not take place over the whole area, but in the form of patterns, characters or the like, and the non-hardened areas according to Curing step are removed. Use of a liquid crystal polymer for securing and / or authenticity identification of data carriers such as security, ID card or the like. Method for machine testing a data carrier according to claim 1, characterized in that the security element is illuminated with a light source at at least a predetermined angle and the polarization properties and / or the spectral properties of the reflected light are checked with suitable detector arrangements. A method according to claim 30, characterized in that the properties of the reflected light are checked under a plurality of illumination and / or observation angles. Arrangement for performing the method according to claim 30 or 31, characterized by a light source (129) which illuminates the security element (130) at at least a predetermined angle, one or more color filters (141, 161) for checking the spectral properties of the reflected light, - a polarization-optical component (152, 162), - A beam splitter (143) for splitting the reflected light into partial beams of different polarization and - Polarizing optical components (148, 149, 155, 157) and detectors (146, 147, 156, 158) for measuring the intensity of the partial beams. Arrangement according to claim 32, characterized in that the reflected beam (132) is coupled into a fiber optic system (154) with optics (153), the beam splitters and polarizing components (155, 157) being integrated in the system.

Images